Lecture 6Chapter 20 Induced voltage and inductance
Saturday, February 22, 14
You may ignore
20.4, 20.6, and 20.7
Saturday, February 22, 14
Connections)Between)Electricity)and)Magnetism)
• 1819)– Hans)Christian)Oersted)discovered)an)electric)current)exerts)a)force)on)a)magnetic)compass.)
– First)evidence)of)a)link)between)electricity)and)magnetism)
• 1831)– Faraday)and)Henry)showed)a)changing)magnetic)field)could)induce)an)electric)current)in)a)circuit.)
– Led)to)Faraday�s)Law)
Introduction)
This will result in electricity generation and the modern world
Saturday, February 22, 14
Faraday�s'Experiment'–'Set'Up'
• A'current'can'be'produced'by'a'changing'magnetic'field.'– First'shown'in'an'experiment'by'Michael'Faraday'• A'primary'coil'is'connected'to'a'battery.'
• A'secondary'coil'is'connected'to'an'ammeter.'
Section'20.1'
Saturday, February 22, 14
Faraday�s'Experiment'
• There'is'no'battery'in'the'secondary'circuit.'• When'the'switch'is'closed,'the'ammeter'reads'a'current'and'then'returns'to'zero.'
• When'the'switch'is'opened,'the'ammeter'reads'a'current'in'the'opposite'direction'and'then'returns'to'zero.'
• When'there'is'a'steady'current'in'the'primary'circuit,'the'ammeter'reads'zero.'
Section'20.1'
Saturday, February 22, 14
Faraday�s'Conclusions'
• An'electrical'current'is'produced'by'a'changing'magnetic'field.'
• The'secondary'circuit'acts'as'if'a'source'of'emf'were'connected'to'it'for'a'short'time.'
• It'is'customary'to'say'that'an'induced'emf'is'produced'in'the'secondary'circuit'by'the'changing'magne4c'field.'
Section'20.1'
Saturday, February 22, 14
Magnetic)Flux)
• The)emf)is)actually)induced)by)a)change)in)the)quantity)called)the)magne&c(flux)rather)than)simply)by)a)change)in)the)magnetic)field.)
• Magnetic)flux)is)defined)in)a)manner)similar)to)that)of)electrical)flux.)
• Magnetic)flux)is)proportional)to)both)the)strength)of)the)magnetic)field)passing)through)the)plane)of)a)loop)of)wire)and)the)area)of)the)loop.)
Section)20.1)
Saturday, February 22, 14
Magnetic)Flux,)2)• You)are)given)a)loop)of)
wire.)• The)wire)is)in)a)uniform)
magnetic)field.))• The)loop)has)an)area)A.)• The)flux)is)defined)as)
– ΦB)=)B⊥A)=)B)A)cos)θ)• θ)is)the)angle)between)B)and)the)normal)to)the)plan)
• SI)unit:)weber)(Wb))– Wb)=)T).))m2)
)
Section)20.1)
Saturday, February 22, 14
Magnetic)Flux,)3)
• When)the)field)is)perpendicular)to)the)plane)of)the)loop,)as)in)a,)θ)=)0)and)ΦB)=)ΦB,)max)=)BA)
• When)the)field)is)parallel)to)the)plane)of)the)loop,)as)in)b,)θ)=)90°)and)ΦB)=)0)– The)flux)can)be)negative,)for)example)if)θ)=)180°)
Section)20.1)
HW #2Saturday, February 22, 14
Magnetic)Flux,)Final)
• The)flux)can)be)visualized)with)respect)to)magnetic)field)lines.)– The$value$of$the$magne/c$flux$is$propor/onal$to$the$total$number$of$lines$passing$through$the$loop.$
• When)the)area)is)perpendicular)to)the)lines,)the)maximum)number)of)lines)pass)through)the)area)and)the)flux)is)a)maximum.)
• When)the)area)is)parallel)to)the)lines,)no)lines)pass)through)the)area)and)the)flux)is)0.)
Section)20.1)
Saturday, February 22, 14
A uniform 4.5-T magnetic field passes perpendicularly through the plane of a wire loop 0.10 m2 in area. What flux passes through the loop?a.5.0 Tm2
b.0.45 Tm2
c.0.25 Tm2
d.0.135 Tm2
Saturday, February 22, 14
Nature abhors a change in flux
A changing flux will generate a current in a conductor which in turn generates a magnetic field which opposes the change in flux
Saturday, February 22, 14
Fig. 20-4, p. 692
In A you are increasing the flux, in C you are decreasing it
Saturday, February 22, 14
Electromagnetic-Induction-–-Results-of-the-Experiment-
• A-current-is-set-up-in-the-circuit-as-long-as-there-is-rela%ve'mo%on-between-the-magnet-and-the-loop.-– The-same-experimental-results-are-found-whether-the-loop-moves-or-the-magnet-moves.-
• The-current-is-called-an-induced'current-because-is-it-produced-by-an-induced-emf.-
Section-20.2-
Saturday, February 22, 14
Faraday�s'Law'and'Electromagnetic'Induction'
• The'instantaneous'emf'induced'in'a'circuit'equals'the'negative'time'rate'of'change'of'magnetic'flux'through'the'circuit.'
• If'a'circuit'contains'N'tightly'wound'loops'and'the'flux'changes'by'ΔΦB'during'a'time'interval'Δt,'the'average'emf'induced'is'given'by'Faraday�s'Law:'
Section'20.2'
Saturday, February 22, 14
A sensitive ammeter is connected to a wire loop and placed within the magnetic field of a strong horseshoe magnet. The ammeter shows a deflection when:a.the wire is moved parallel to the field.b.the wire is moved perpendicularly to the field.c.neither wire nor magnet is moving.d.The wire's axis is parallel to the field.
A square coil, enclosing an area with sides 2.0 cm long, is wrapped with 2 500 turns of wire. A uniform magnetic field perpendicular to its plane is turned on and increases to 0.25 T during an interval of 1.0 s. What average voltage is induced in the coil?a.0.25 Vb.0.12 Vc.2.0 Vd.2.5 V
A 10-turn square coil of area 0.036 m2 and a 20-turn circular coil are both placed perpendicular to the same changing magnetic field. The voltage induced in each of the coils is the same. What is the area of the circular coil?a.0.072 m2
b.0.60 m2
c.0.018 m2
d.0.036 m2
Saturday, February 22, 14
There is another way to change the flux.What is it?
Saturday, February 22, 14
Faraday�s'Law'and'Lenz�'Law'
• The'change'in'the'flux,'ΔΦB,'can'be'produced'by'a'change'in'B,'A'or'θ'– Since'ΦB'='B'A'cos'θ'
• The'negative'sign'in'Faraday�s'Law'is'included'to'indicate'the'polarity'of'the'induced'emf,'which'is'found'by'Lenz�%Law.%%– The'current'caused'by'the'induced'emf'travels'in'the'direction'that'creates'a'magnetic'field'with'flux'opposing'the'change'in'the'original'flux'through'the'circuit.'
Section'20.2'
Saturday, February 22, 14
Lenz�%Law%–%Example%• The%magnetic%field,%%%%,%
becomes%smaller%with%time.%– This%reduces%the%flux.%
• The%induced%current%will%produce%an%induced%field,%%%%%%
%,%in%the%same%direction%as%the%original%field.%
Section%20.2%
Hw 9Saturday, February 22, 14
Applications+of+Faraday�s+Law+–+Ground+Fault+Interrupters+
• The+ground+fault+interrupter+(GFI)+is+a+safety+device+that+protects+against+electrical+shock.+– Wire+1+leads+from+the+wall+outlet+
to+the+appliance.+– Wire+2+leads+from+the+appliance+
back+to+the+wall+outlet.+– The+iron+ring+confines+the+
magnetic+field,+which+is+generally+0.+
– If+a+leakage+occurs,+the+field+is+no+longer+0+and+the+induced+voltage+triggers+a+circuit+breaker+shutting+off+the+current.+
Section+20.2+
Saturday, February 22, 14
Application*of*Faraday�s*Law*–*Motional*emf*
• A*straight*conductor*of*length*ℓ*moves*perpendicularly*with*constant*velocity*through*a*uniform*field.*
• The*electrons*in*the*conductor*experience*a*magnetic*force.*– F*=*q*v*B*
• The*electrons*tend*to*move*to*the*lower*end*of*the*conductor.*
Section*20.3*
Saturday, February 22, 14
Motional(emf(• As(the(negative(charges(accumulate(at(the(base,(a(net(
positive(charge(exists(at(the(upper(end(of(the(conductor.(• As(a(result(of(this(charge(separation,(an(electric(field(is(
produced(in(the(conductor.(• Charges(build(up(at(the(ends(of(the(conductor(until(the(
downward(magnetic(force(is(balanced(by(the(upward(electric(force.(
• There(is(a(potential(difference(between(the(upper(and(lower(ends(of(the(conductor.(
Section(20.3(
Saturday, February 22, 14
Motional(emf,(Cont.(
• The(potential(difference(between(the(ends(of(the(conductor(can(be(found(by(– ΔV(=(E(l(=(B(ℓ(v(– The(upper(end(is(at(a(higher(potential(than(the(lower(end(
• A(potential(difference(is(maintained(across(the(conductor(as(long(as(there(is(motion(through(the(field.(– If(the(motion(is(reversed,(the(polarity(of(the(potential(difference(is(also(reversed.(
Section(20.3(
Saturday, February 22, 14
Motional(emf(in(a(Circuit(• Assume(the(moving(bar(has(
zero(resistance.(• As(the(bar(is(pulled(to(the(right(
with(a(given(velocity(under(the(influence(of(an(applied(force,(the(free(charges(experience(a(magnetic(force(along(the(length(of(the(bar.(
• This(force(sets(up(an(induced(current(because(the(charges(are(free(to(move(in(the(closed(path.(
Section(20.3(
Fig. 20-17, p. 698
As the bar is pulled to the
right there is a charge
separation in the bar
This gives rise to a vertical velocity of the protons in the bar leading to a force to the left
Saturday, February 22, 14
Motional(emf(in(a(Circuit,(Cont.(• The(changing(magnetic(flux(
through(the(loop(and(the(corresponding(induced(emf(in(the(bar(result(from(the(change'in'area(of(the(loop.(
• The(induced,(motional,(emf(acts(like(a(battery(in(the(circuit.(
Section(20.3(
Fig. 20-16b, p. 698
Saturday, February 22, 14
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Example 20.4
Saturday, February 22, 14
A straight wire of length is oriented east-west and is in a magnetic field B pointing north. The wire is moving downward at a constant speed v. Which end of the rod is positively charged?a.neitherb.the east endc.the west endd.both ends
An airplane with a wingspan of 60.0 m flies parallel to the Earth’s surface at a point where the downward component of the Earth's magnetic field is 0.400 x l0-4 T. If the induced potential between wingtips is 0.900 V, what is the plane’s speed?a.250 m/sb.338 m/sc.375 m/sd.417 m/s
A large jetliner with a wingspan of 40 m flies horizontally and due north at a speed of 300 m/s in a region where the magnetic field of the earth is 60 µT directed 50° below the horizontal. What is the magnitude of the induced emf between the ends of the wing?a.250 mVb.350 mVc.550 mVd.750 mV
Saturday, February 22, 14
Generators)
• Alternating)Current)(AC))generator)– Converts)mechanical)energy)to)electrical)energy)– Consists)of)a)wire)loop)rotated)by)some)external)means)
– There)are)a)variety)of)sources)that)can)supply)the)energy)to)rotate)the)loop.)• These)may)include)falling)water,)heat)by)burning)coal)to)produce)steam)
Section)20.4)
Saturday, February 22, 14
Motors&
• Motors&are&devices&that&convert&electrical&energy&into&mechanical&energy.&– A&motor&is&a&generator&run&in&reverse.&
• A&motor&can&perform&useful&mechanical&work&when&a&shaft&connected&to&its&rotating&coil&is&attached&to&some&external&device.&
Section&20.4&
Saturday, February 22, 14
Self%inductance-
• Self%inductance-occurs-when-the-changing-flux-through-a-circuit-arises-from-the-circuit-itself.-– As-the-current-increases,-the-magnetic-flux-through-a-loop-due-to-this-current-also-increases.-
– The-increasing-flux-induces-an-emf-that-opposes-the-change-in-magnetic-flux.-
– As-the-magnitude-of-the-current-increases,-the-rate-of-increase-lessens-and-the-induced-emf-decreases.-
– This-decreasing-emf-results-in-a-gradual-increase-of-the-current.-
Section-20.5-
Saturday, February 22, 14
Self%inductance,.Cont..
• The.self%induced.emf.must.be.proportional.to.the.time.rate.of.change.of.the.current..
– L.is.a.proportionality.constant.called.the.inductance.of.the.device..
– The.negative.sign.indicates.that.a.changing.current.induces.an.emf.in.opposition.to.that.change..
Section.20.5.
Saturday, February 22, 14
Self%inductance,.Final.
• The.inductance.of.a.coil.depends.on.geometric.factors..
• The.SI.unit.of.self%inductance.is.the.Henry.– .1.H.=.1.(V.?.s)./.A.
• You.can.determine.an.expression.for.L.
Section.20.5.
Saturday, February 22, 14
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Saturday, February 22, 14
The current in a coil with a self-inductance of 1.5 mH increases from 0 to 1.0 A in a tenth of a second. What is the induced emf in the coil?a.15 mVb.30 mVc.0.10 Vd.0.30 V
What is the self-inductance in a coil that experiences a 3.0-V induced emf when the current is changing at a rate of 110 A/s?a.83 mHb.45 mHc.37 mHd.27 mH
Saturday, February 22, 14
Key ConceptsNature abhors a change in flux
Motional emfs - charges separate in a moving conductor setting up a potential difference
Law of induction - a changing flux sets up a potential difference
Self induction - turning on a current generates a flux of field that opposes the change in current
Saturday, February 22, 14
Key Equations
Saturday, February 22, 14